Multi-row wiring member for semiconductor device and method for manufacturing the same

ABSTRACT

A multi-row wiring member for semiconductor device configured of a plurality of wiring members arrayed in a matrix includes a resin layer, a first plating layer forming internal terminals, a plating layer forming wiring portions and a second plating layer forming external terminals. The first plating layer is formed in the resin layer with lower faces thereof uncovered in the bottom surface of the resin layer. The plating layer forming wiring portions is formed on the first plating layer in the resin layer. The second plating layer is formed on partial areas within areas of the plating layer forming wiring portions, with upper faces thereof being uncovered on a top-surface side of the resin layer. On a bottom-surface side of the resin layer, a resin frame is integrally formed with the resin layer at the margin around an aggregate of individual wiring members for semiconductor devices arrayed in a matrix.

CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

This application is a continuation of PCT International Application No. PCT/JP2017/003031, filed on Jan. 27, 2017, and claims the benefit of Japanese Patent Application No. 2016-101948 filed in Japan on May 20, 2016. The contents of PCT International Application No. PCT/JP2017/003031 and Japanese Patent Application No. 2016-101948 are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1) Field of the Invention

The present invention relates to a multi-row wiring member for semiconductor device for achieving flip-chip mounting of semiconductor elements thereon and a method for manufacturing the same.

2) Description of Related Art

Conventionally, of substrates for semiconductor devices, there are those of a type intended to complete a semiconductor device by peeling off a base material thereof after mounting a semiconductor element thereon and sealing the entirety with a resin, as described in Japanese Patent Application Laid-Open No. 2015-185619.

As shown in FIG. 5A, the substrate for semiconductor device described in JP Patent Application Laid-Open No. 2015-185619 is provided, on a base material 51 made of a stainless steel material or the like, with a semiconductor-element mounting portion 52 a and terminal portions 52 b, both of which are formed of a metal plating layer. Each of the terminal portions 52 b is formed to have an internal terminal face 52 b 1 and an external terminal face 52 b 2 in a back-to-back arrangement.

On the semiconductor-element-mounting side of each of the semiconductor-element mounting portion 52 a and the terminal portions 52 b, an overhang 52 a 1 or 52 b 3 is formed around the upper edge thereof. On the base-material side of the semiconductor element mounting portion 52 a and the terminal portions 52 b, a thin film made of Au or the like is formed by plating so that the external terminal faces assure appropriate soldering in mounting of a semiconductor device to be manufactured.

Manufacturing of a semiconductor device upon use of the substrate for semiconductor device of FIG. 5A is conducted through mounting a semiconductor element 53 on the semiconductor-element mounting portion 52 a, connecting electrodes of the semiconductor element 53 and the terminal portions 52 b with wires 54, forming a sealing resin portion 55 by sealing the side where the semiconductor element 53 is mounted, and then peeling off the base material 51, to complete a semiconductor device (see FIGS. 5B-5D).

Also, conventionally, of substrates for semiconductor device, there are those of a type in which internal terminals, external terminals and wiring portions are formed by metal plating on a metal sheet, to be used for a semiconductor device with BGA (Ball Grid Array) structure, as described in Japanese Patent Application Laid-Open No. 2009-164594.

The substrate for semiconductor device described in JP Patent Application Laid-Open No. 2009-164594 is configured, as shown in FIG. 6A, so that, on a metal sheet 61 as a base material, formed is an external-terminal-side plating layer having external terminal portions 62, on which formed with a same shape as the external-terminal-side plating layer is an intermediate layer 63, on which further formed with the same shape as the intermediate layer 63 is an internal-terminal-side plating layer having internal terminal portions 64. This substrate for semiconductor device is configured so that the surface of the internal-terminal-side plating layer having internal terminal portions 64, which are to achieve electrical connection with a semiconductor element, is to be an uppermost surface and so that the height from the metal sheet to the uppermost surface is substantially uniform over the entirety.

In manufacturing a semiconductor device, the substrate for semiconductor device described in JP Patent Application Laid-Open No. 2009-164594 is used with a metal-sheet-side surface of the external-terminal-side plating layer being in contact with a surface of the metal sheet as external terminal faces and a farther surface of the internal-terminal-side plating layer in reference to the metal sheet being uncovered as internal terminal faces. To be specific, the following steps are to be performed; mounting a semiconductor element 65 on the internal-terminal-face side of the substrate for semiconductor device and fix it with an adhesive layer 66, connecting electrodes of the semiconductor element and internal terminal portions 64 with wires 67, forming a sealing resin portion 68 by sealing the entirety with a resin, and removing the metal sheet by dissolving it by means of etching or the like so that the back surface of the sealing resin is made uncovered along with faces of the external-terminal-side plating layer having the external terminal portions 62. After that, the following steps are to be performed; forming a solder resist layer 69 covering the entire surface of the uncovered external-terminal-side plating layer, forming openings 70 that uncovers the external terminal portions 62 alone (see FIGS. 6B-6E), and embedding solder balls into the openings 70 at which the external terminal portions 62 are uncovered, to connect the external terminal portions 62 with external equipment (see FIG. 6F).

Since the external-terminal-side plating layer having external terminal portions 62, the intermediate layer 63 and the internal-terminal-side plating layer having internal terminal portions 64 are overlaid one on another to have a same shape so that wiring portions are formed between the internal terminal portions 64 and the external terminal portions 62, the pitch of the internal terminals and the external terminals is adjustable in accordance with a design of the wiring portion in the substrate for semiconductor device described in JP Patent Application Laid-Open No. 2009-164594.

The inventors of the present application, upon repeated trial and error at the stage before introducing the present invention, have devised a wiring member for semiconductor device that enables manufacturing of a highly-reliable resin-sealed semiconductor device through a reduced number of steps and a manufacturing method for the same wiring member; the wiring member enables reduction in thickness and size of the semiconductor device, improves adhesion between a plating film that forms terminal portions and a resin, achieves uniform height of a surface of the internal-terminal-side plating layer on which the semiconductor element is to be mounted and internal terminal portions to be electrically connected with the semiconductor element, eliminates, in the manufacturing process for the semiconductor device, the step of removing the metal sheet by etching and the step of forming openings that uncover external terminal portions alone, and moderating a warpage of the sealing resin as cured.

As a result of further study and consideration, the inventors of the present application have found that this prototypal wiring member for semiconductor device and the method for manufacturing the same as devised involved problems to be improved for mass-production of semiconductor devices.

SUMMARY OF THE INVENTION

A multi-row wiring member for semiconductor device according to one embodiment mode of the present invention configured of a plurality of wiring members for semiconductor devices arrayed in a matrix includes: a resin layer; a first plating layer, which is to become internal terminals, formed in the resin layer with lower faces thereof being uncovered at predetermined sites in a bottom surface of the resin layer; a plating layer that is to become wiring portions, connected with the first plating layer in the resin layer; and a second plating layer, which is to become external terminals, formed, in the resin layer on partial areas within areas of the plating layer that is to become wiring portions, with upper faces thereof being uncovered on a top-surface side of the resin layer, wherein a side view of each laminated piece of the plating layers forming one of the internal terminals, one of the wiring portions, and one of the external terminals substantially has an L shape or an inverted T shape, and wherein, on a bottom-surface side of the resin layer, a resin frame portion is formed integrally with the resin layer at a site that is to be a margin around an aggregate formed of the individual wiring members for semiconductor devices arrayed in a matrix.

A method according to one embodiment mode of the present invention for manufacturing a multi-row wiring member for semiconductor device configured of a plurality of wiring members for semiconductor devices arrayed in a matrix includes: a step of forming, on a front surface of a metal sheet, a first resist mask having an opening at a site that is to be a margin around an aggregate of individual wiring members for semiconductor devices arrayed in a matrix; a step of performing half-etching from a front-surface side of the metal sheet, to form a concavity in a metal surface left uncovered at the opening; a step of peeling off the first resist mask formed on the front surface of the metal sheet; a step of forming, on the front surface of the metal sheet, a second resist mask covering the concavity and having pattern-A openings; a step of forming, in the pattern-A openings, a first plating layer, which is to become internal terminals, and a plating layer that is to become wiring portions, connected with the first plating layer; a step of peeling off the second resist mask formed on the front surface of the metal sheet; a step of forming, on a front-surface side of the metal sheet, a third resist mask covering the concavity and having pattern-B openings that leave uncovered partial areas within areas of the plating layer that is to become wiring portions; a step of forming a second plating layer, which is to become external terminals, in the pattern-B openings; a step of peeling off the third resist mask formed on the front surface of the metal sheet; a step of forming a resin layer on the metal sheet and the plating layer that is to become wiring portions at sites free from the second plating layer while leaving upper faces of the second plating layer uncovered and filling the concavity; and a step of removing the metal sheet by etching or peeling.

These and other features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1E are diagrams that show the configuration of the multi-row wiring member for semiconductor device according to the first embodiment mode of the present invention, where FIG. 1A is a plan view as viewed from the external-terminal side, FIG. 1B is an enlarged view of a part of FIG. 1A, FIG. 1C is a sectional view taken along A-A of FIG. 1B, FIG. 1D is a plan view that shows one example of a laminated piece of plating layers forming an internal terminal, a wiring portion and an external terminal in an individual wiring member for semiconductor device, and FIG. 1E is a sectional view of FIG. 1D.

FIGS. 2A-20 are explanatory diagrams that show the manufacturing process for the multi-row wiring member for semiconductor device shown in FIGS. 1A-1E.

FIGS. 3A-3F are explanatory diagrams that show one example of the manufacturing process for a resin-sealed semiconductor device using the multi-row wiring member for semiconductor device of the first embodiment mode manufactured via the manufacturing process shown in FIGS. 2A-20.

FIGS. 4A-4B are diagrams that show the state where flip-chip mounting of a semiconductor element on the individual wiring member for semiconductor device is achieved in the manufacturing process shown in FIGS. 3A-3F, where FIG. 4A is a plan view as viewed from the semiconductor-element-mounting side, and FIG. 4B is a sectional view of FIG. 4A.

FIGS. 5A-5D are explanatory diagrams that show one example of the manufacturing process for semiconductor device using a conventional substrate for semiconductor device.

FIGS. 6A-6F are explanatory diagrams that show another example of the manufacturing process for semiconductor device using a conventional substrate for semiconductor device.

FIGS. 7A-7B are diagrams that show the configuration of the wiring member for semiconductor device according to the invention devised at the stage before introduction of the present invention, where FIG. 7A is a plan view and FIG. 7B is a sectional view.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Preceding the explanation of the embodiment mode, the circumstances leading up to the present invention and the function and effect of the present invention will be described.

The inventors of the present application, upon repeated trial and error at the stage before introducing the present invention, have devised a wiring member for semiconductor device that enables manufacturing of a highly-reliable resin-sealed semiconductor device through a reduced number of steps and a manufacturing method of the same wiring member; the wiring member achieves uniform height of the internal terminal surface on which the semiconductor element is to be mounted and internal terminal portions to be electrically connected with the semiconductor element, and eliminates, in the manufacturing process for the semiconductor device, the step of removing the metal sheet by etching and the step of forming openings that uncover external terminal portions alone.

Invention Devised at the Stage Before Introduction of the Present Invention

As shown in FIG. 7B, in the wiring member for semiconductor device according to the invention devised before introduction of the present invention, a first plating layer 11, which is to become internal terminals, is formed in a resin layer 15 with lower faces thereof being uncovered at predetermined sites in a bottom surface 15 a of the resin layer 15 at a same level as the bottom surface 15 a, a plating layer 12 that is to become wiring portions is formed in the resin layer 15 on the first plating layer 11 with plating boundaries thereof coinciding with those of the first plating layer 11, and a second plating layer 13, which is to become external terminals, is further formed on partial areas within areas of the plating layer 12 that is to become wiring portions, with upper faces thereof being uncovered on the side of the top surface of the resin layer 15, so that a side view of each laminated piece formed of one of the internal terminals, one of the wiring portions, and one of the external terminals substantially has an L shape (or an inverted T shape).

Forming the laminated pieces of the plating layers in which the internal terminals and the external terminals are connected via the wiring portions as in the wiring member for semiconductor device according to the invention shown in FIGS. 7A-7B makes it possible to adjust the respective mounting pitches of the internal terminals and the external terminals in accordance with design.

Each laminated piece of plating layers in which an internal terminal and an external terminal are connected via a wiring portion, if formed to have substantially an L shape or an inverted T shape in a side view, is improved in adhesion to the resin layer and thus prevents the metal film forming the terminals from coming off the resin layer.

Also, in the configuration in which the second plating layer 13, which is to become external terminals, is formed on partial areas within areas of the plating layer 12 that is to become wiring portions, the second plating layer 13 can be made small and thus, as the external terminals left uncovered on the back surface side of the semiconductor device, is prevented from dropping or coming off.

Also, at sites corresponding to openings in a resin layer, which would be provided during the manufacturing process for a semiconductor device in the case of a conventional substrate for semiconductor device, the external terminals having a thickness different from the internal terminals and the wiring portions are pre-provided, and the internal terminals and the wiring portions are sealed with the resin layer while only the external terminals are uncovered on the side of the top surface of the resin layer. This configuration makes it unnecessary to provide an insulating layer having openings at connection faces with external members in the manufacturing process for a semiconductor device, to result in a reduced number of steps in the manufacturing process for a semiconductor device and improved productivity.

A detailed description will be made in this regard.

The inventors of the present application have conceived that the arrangement of electrical connection faces of internal terminals and external terminals of a substrate for semiconductor device used in manufacturing a semiconductor device should be inverted in reference to that of a conventional substrate for a semiconductor device.

That is, the conventional semiconductor device substrate is configured so that, when a semiconductor device is to be manufactured, the external terminal surface is used in a state of being uncovered on the side of the metal sheet and the internal terminal surface is used in a state of being uncovered on the side farther from the metal sheet.

In contrast, in the wiring member for a semiconductor device of the invention shown in FIG. 7A-7B, the plating layer that forms external terminals is configured to be higher, from a metal sheet that was used in manufacturing the substrate for semiconductor device, than the plating layers that form internal terminals and wiring portions, on the basis of the conception that, when a semiconductor device is to be manufactured, the external terminal surface is used in a state of being uncovered on the side farther from the metal sheet that was used in manufacturing the substrate for semiconductor device and the internal terminal surface is used in a state of being uncovered on the side of the metal sheet.

For example, when the metal sheet, which was used in manufacturing the wiring member for semiconductor device of the invention shown in FIGS. 7A-7B, is dissolved and removed by etching or the like, the faces of the first plating layer 11, which is to become internal terminals, on the metal-sheet-removal side are made uncovered at a uniform level (level difference of 1 μm or smaller) in conformance with the surface of the metal sheet. The metal sheet is a rolled material commonly used for lead frames.

Here, a semiconductor element is mounted on the first plating layer 11 as in the case of the semiconductor device using the conventional substrate for semiconductor device. Since the faces of the first plating layer 11 are uncovered at a uniform level, the connection surface is flat in its entirety, to assure stable connection.

In this case, the external terminals have to be uncovered at the faces farther from the metal sheet. Therefore, the inventors of the present application have devised the wiring member for semiconductor device of the invention shown in FIGS. 7A-7B in which the external terminals having a height different from the internal terminals and wiring portions are formed so that a resin layer is formed on sites free from the second plating layer while leaving upper faces of the second plating layer uncovered with the metal sheet being removed by etching, by overlaying plating only on the sites where the external terminals are to be made after applying plating on the metal sheet at sites where the internal terminals, the wiring portions and the external terminals are to be formed.

As in the case of the wiring member for semiconductor device according to the invention shown in FIG. 7A-7B, in the configuration in which the external terminals have a difference in height from the internal terminals and the wiring portions so that only the internal terminals and the wiring portions are sealed with the resin layer while only the external terminals are left uncovered on the side of the top surface of the resin layer, it is possible to dispense with a step of removing the metal sheet by etching and a step of processing the resin layer for forming openings at sites where faces for connection with external members are to be formed in the manufacturing process for semiconductor device, to result in a reduced number of steps and improved productivity.

Also, the wiring member for semiconductor device according to the invention shown in FIGS. 7A-7B is configured to include only the laminated plating film and the resin layer, and thus, in resin-sealing after flip-chip mounting, only the resin layer and the uncovered plating film of the wiring member for semiconductor device are sealed with a sealing resin, while a surface of a base material (metal sheet), which greatly differs in expansion coefficient from the resin, is not contacted with the sealing resin. Therefore, warpage after curing of the sealing resin is moderated. To be specific, in the case of resin-sealing of the resin layer, since the resin layer and the sealing resin are materials having similar physical characteristics, a difference between the two materials in thermal shrinkage or thermal expansion after curing of the sealing resin is smaller in comparison with the case of resin-sealing of the metal sheet forming a base material. In addition, no base material is removed after formation of the sealing resin portion. As a result, warpage after curing of the sealing resin is moderated.

Furthermore, according to the wiring member for semiconductor device of the invention shown in FIGS. 7A-7B, since removal of the metal sheet as a base material by etching and processes (application of solder resist, exposure, and development) for forming openings at connection faces with external equipment are dispensable in the manufacturing process for a semiconductor device, seeping-in moisture or liquid agent could not deteriorate the semiconductor device.

Problems Involved in the Invention Devised at the Stage Before Introduction of the Present Invention

Upon a further study and consideration, the inventors of the present application have found that the wiring member for semiconductor device of the invention shown in FIGS. 7A-7B had the following problems to be solved for responding to the demand for mass production.

Such a wiring member for semiconductor device as used for manufacturing semiconductor devices is formed as a multi-row wiring member for semiconductor devices in which individual wiring members for semiconductor devices are arrayed in a matrix, for the purpose of obtaining a large number of semiconductor devices at one time.

In the wiring member for semiconductor device shown in FIGS. 7A-7B, the internal terminals, the wiring portions and the external terminals are formed from the plating layers 11, 12 and 13 and are fixed by the resin layer 15 with the wiring member in its entirety having a shape of a thin sheet. When a plurality of such wiring members for semiconductor devices as having a thin sheet shape are formed into a multi-row matrix, the area of the aggregate of wiring members for semiconductor devices comes to be enormously wide in reference to the thickness of the resin layer. Therefore, the entire surface of the aggregate of wiring members for semiconductor devices easily causes deflection, which could unfavorably affect manufacturing of semiconductor devices. For example, when a sheet of an aggregate of multi-row substrates for semiconductor devices is to be conveyed for the purpose of carrying out the flip-chip mounting step in the state where a laminated plating film is buried in a resin layer, since the sheet has too low a strength to be a sheet for mounting semiconductor elements thereon, it could be deformed during conveyance.

Function and Effect of the Present Invention

Then, upon repeated trial and error on the basis of study and consideration of the above-described problem in the invention shown in FIGS. 7A-7B, the inventors of the present application have devised the present invention, which can maintain the above-described advantage as well as can solve the above-described problem of the invention shown in FIGS. 7A-7B.

The multi-row wiring member for semiconductor device according to the embodiment mode of the present invention is configured of a plurality of such wiring members for semiconductor devices of the invention as shown in FIGS. 7A-7B arrayed in a matrix, wherein, on the bottom-surface side of the resin layer, a resin frame portion is integrally formed with the resin layer at a site that is to be a margin around an aggregate of individual wiring members for semiconductor devices arrayed in a matrix.

If a resin frame portion is integrally formed with the resin layer on the bottom-surface side of the resin layer at a site that is to be a margin around an aggregate of wiring members for semiconductor devices arrayed in a matrix as in the multi-row wiring member for semiconductor device according to the embodiment mode of the present invention, the resin frame portion reinforces the multi-row wiring member for semiconductor device, to assure a strength that makes the multi-row wiring member for semiconductor device hardly deformable even if conveyed.

It is noted that an aggregate of wiring members for semiconductor devices as a unit to be provided with a resin frame portion may be the entire region (one sheet) of the multi-row wiring member for semiconductor device or may be each of plurality of blocks into which the entire region is divided.

Also, in the multi-row wiring member for semiconductor device of the embodiment mode of the present invention, the plating layer that is to become wiring portions is formed on the first plating layer preferably with plating boundaries thereof coinciding with those of the first plating layer.

This structure allows a large area to be secured for internal terminals and thus the product is widely applicable to a variety of semiconductor elements different in pitch of electrodes.

Also, in the multi-row wiring member for semiconductor device of the embodiment mode of the present invention, the upper surface of the plating layer that is to become wiring portions formed on the first plating layer preferably is a roughened surface.

This structure improves adhesion between a site, in the plating layer that is to become wiring portions, not covered with the second plating layer and the resin layer. Thus, even a thin plating layer having a thickness of 5 μm or less formed of the first plating layer and the plating layer that is to become wiring portions is prevented from coming off the resin layer.

Also, in the multi-row wiring member for semiconductor device of the embodiment mode of the present invention, the bottom surface of the resin layer, in which the first plating layer appears as uncovered, preferably is a rough surface.

This structure improves adhesion to an adhesive layer to be used in mounting a semiconductor element and to a sealing resin to be used for sealing after mounting of the semiconductor element.

The other configurations, functions and effects are substantially the same as the wiring member for semiconductor device of the invention shown in FIGS. 7A-7B.

The multi-row wiring member for semiconductor device according to the embodiment mode of the present invention can be manufactured by the method including: a step of forming, on a front surface of a metal sheet, a first resist mask having an opening at a site that is to be a margin around an aggregate of wiring members for semiconductor devices arrayed in a matrix and of forming, on a back surface of the metal sheet, a first resist mask covering an entire surface; a step of performing half-etching from a front-surface side of the metal sheet, to form a concavity in a metal surface left uncovered at the opening; a step of peeling off the first resist mask formed on the front surface of the metal sheet; a step of forming, on the front surface of the metal sheet, a second resist mask covering the concavity and having pattern-A openings; a step of forming, in the pattern-A openings, a first plating layer, which is to become internal terminals, and a plating layer that is to become wiring portions, connected with the first plating layer; a step of peeling off the second resist mask formed on the front surface of the metal sheet; a step of forming, on a front-surface side of the metal sheet, a third resist mask covering the concavity and having pattern-B openings that leave uncovered partial areas within areas of the plating layer that is to become wiring portions; a step of forming a second plating layer, which is to become external terminals, in the pattern-B openings; a step of peeling off the third resist mask formed on the front side of the metal sheet and the first resist mask formed on the back side of the metal sheet; a step of forming a resin layer on the metal sheet and the plating layer that is to become wiring portions at sites free from the second plating layer while leaving upper faces of the second plating layer uncovered and filling the concavity; and a step of removing the metal sheet by etching or peeling.

The plating layer that is to become wiring portions is preferably formed on the first plating layer such that plating boundaries thereof coincides with those of the first plating layer.

This manner of formation allows a large area to be secured for internal terminals and thus the product is widely applicable to a variety of semiconductor elements different in pitch of electrodes.

Also, it is preferred that the upper surface of the plating layer that is to become wiring portions undergoes roughening treatment after formation of the plating layer that is to become wiring portions and before formation of the second resist mask or that the plating layer that is to become wiring portions is formed as a roughened plating layer.

Such a step improves adhesion between a site, in the plating layer that is to become wiring portions, not covered with the second plating layer and the resin layer. Thus, even a thin plating layer having a thickness of 5 μm or less formed of the first plating layer and the plating layer that is to become wiring portions is prevented from coming off the resin layer.

Also, it is preferred to include a step of carrying out roughening treatment of the surface of the metal sheet upon using, as a mask, the plating layer that is to become wiring portions formed on the metal sheet after removal of the second resist mask formed on the front surface of the metal sheet.

This step improves adhesion to an adhesive layer used in mounting a semiconductor element and to a sealing resin used for sealing after mounting of the semiconductor element, because the bottom surface of the resin layer, when the metal sheet is removed, is made uncovered as a rough surface.

Therefore, the embodiment mode of the present invention can provide a multi-row wiring member for semiconductor device that enables mass production of a highly-reliable resin-sealed semiconductor device with high yield through a reduced number of steps and a manufacturing method of the same multi-row wiring member for semiconductor device; the wiring member enables reduction in thickness and size of the semiconductor device, improves adhesion between a plating film that forms terminal portions and a resin, achieves uniform height of the internal terminal surface on which the semiconductor element is to be mounted and internal terminal portions to be electrically connected with the semiconductor element, eliminates, in the manufacturing process for the semiconductor device, the step of removing the metal sheet by etching and the step of forming openings that uncover external terminal portions alone, and moderating a warpage of the sealing resin as cured.

In reference to the drawings, the embodiment mode of the present invention will be described below.

First Embodiment Mode

FIGS. 1A-1E are diagrams that show the configuration of the multi-row wiring member for semiconductor device according to the first embodiment mode of the present invention, where FIG. 1A is a plan view as viewed from the external-terminal side, FIG. 1B is an enlarged view of a part of FIG. 1A, FIG. 1C is a sectional view taken along A-A of FIG. 1B, FIG. 1D is a plan view that shows one example of a laminated piece of plating layers forming an internal terminal, a wiring portion and an external terminal in an individual wiring member for a semiconductor device, and FIG. 1E is a sectional view of FIG. 1D. FIGS. 2A-20 are explanatory diagrams that show the manufacturing process for the multi-row wiring member for semiconductor device shown in FIGS. 1A-1E. FIGS. 3A-3F are explanatory diagrams that show one example of the manufacturing process for a resin-sealed semiconductor device using the multi-row wiring member for semiconductor device of the first embodiment mode manufactured via the manufacturing process shown in FIGS. 2A-20. FIGS. 4A-4B are diagrams that show the state where flip-chip mounting of a semiconductor element on the individual wiring member for semiconductor device is achieved in the manufacturing process shown in FIGS. 3A-3F, where FIG. 4A is a plan view as viewed from the semiconductor-element-mounting side, and FIG. 4B is a sectional view of FIG. 4A.

As shown in FIG. 1A, the multi-row wiring member for semiconductor device of the first embodiment mode has an aggregate of wiring members for semiconductor devices arrayed in a matrix and a resin frame portion 16′.

As shown in FIG. 1C, individual wiring members 10 for semiconductor devices are configured to have a resin layer 15, a first plating layer 11, which is to become internal terminals, a plating layer 12 that is to become wiring portions, and a second plating layer 13, which is to become external terminals.

The first plating layer 11, which is to become internal terminals, is formed in a resin layer 15 with lower faces thereof being uncovered at predetermined sites in a bottom surface 15 a of the resin layer 15 at a same level as the bottom surface 15 a.

The plating layer 12 that is to become wiring portions is formed in the resin layer 15 on the first plating layer 11 with plating boundaries thereof coinciding with those of the first plating layer 11.

The upper surface of the plating layer 12 that is to become wiring portions is a roughened surface. Also, the bottom surface of the resin layer 15, in which the first plating layer 11 appears as uncovered, is a rough surface.

The second plating layer 13, which is to become external terminals, is formed on partial areas within areas of the plating layer 12 that is to become wiring portions (for example, 0.03 mm or more inward from the plating boundaries of the plating layer 12 that is to become wiring portions), with upper faces thereof being uncovered on a top-surface 15 b side of the resin layer 15.

One example of the first plating layer 11 is configured of an Au plating layer, a Pd plating layer and a Ni plating layer overlaid one on another in this order.

The plating layer 12 that is to become wiring portions is configured of an Ni plating layer, Cu plating layer or the like.

One example of the second plating layer 13 is configured of a Ni plating layer, Pd plating layer and an Au plating layer overlaid one on another in this order.

The height H2 of the upper surface of the second plating layer 13 (that is, the upper surface of the Au plating layer) from the bottom surface 15 a of the resin layer 15 is larger than the height H1 of the upper surface of the plating layer 12 that is to become wiring portions from the bottom surface 15 a of the resin layer 15.

A side view of each laminated piece formed of the plating layer 11, which is to become internal terminals, the plating layer 12 that is to become wiring portions, and the second plating layer 13, which is to become external terminals, substantially has an L shape (or an inverted T shape as shown in FIG. 1E).

The resin frame portion 16′ is formed as closely attached to the back-surface 15 a side of the resin layer 15 at the margin around an aggregate of wiring members 10 for semiconductor devices.

The multi-row wiring member for semiconductor device of the first embodiment mode thus configured can be manufactured in the following manner or the like. It is noted that description of pre-treatment and post-treatment including chemical cleaning, aqueous washing and the like carried out in each step of the manufacturing is omitted for convenience's sake. In addition, FIGS. 2A-20 show the manufacturing process as if the resin frame portion should be formed around one wiring member for semiconductor device, for convenience's sake.

First, dry film resist R for a first resist mask and for a second resist mask is made to laminate both surfaces of a metal sheet 1 serving as a substrate shown in FIG. 2A (see FIG. 2B).

Next, the dry film resist R on the front surface side is exposed and developed upon use of a glass mask that carries a pattern for forming an opening at a site that is to be a margin around an aggregate of wiring members for semiconductor devices, whereas the dry film resist R on the back surface side is exposed and developed upon use of a glass mask that allows the entire surface to be exposed. Then, as shown in FIG. 2C, on the front surface, there is formed a first resist mask having an opening at a site that is to be a margin around an aggregate of wiring members for semiconductor devices, whereas, on the back surface, there is formed a first resist mask covering the entire surface. It is noted that the exposure and development is carried out by a conventional known method. For example, dry film resist as covered with a glass mask is irradiated with ultraviolet rays, for lowering its solubility in a developer at sites irradiated with the ultraviolet rays passing through the glass mask and then removing the rest of the dry film resist other than these sites, to thereby form a resist mask. Here, while a negative dry film resist is used as the resist, a negative liquid resist may be used for formation of a resist mask. Further, dry film resist or liquid resist of positive type may be used, for increasing its solubility in a developer at sites irradiated with the ultraviolet rays passing through a glass mask and then removing these sites, to thereby form a resist mask.

Then, half-etching is performed from a front-surface side of the metal sheet, to form a concavity 1 a in a metal surface left uncovered at the opening (See FIG. 2D).

Then, the first resist mask on the front-surface side is peeled off (See FIG. 2E), and the front surface, which has been peeled, is laminated with dry film resist R2 (See FIG. 2F).

Then, the dry film resist R2 on the front-surface side is exposed and developed upon use of a glass mask that carries a pattern (here, referred to as a pattern A) for covering the concavity 1 a and forming, at predetermined sites, internal terminals, wiring portions and the stem of external terminals, to turn into a second resist mask having pattern-A openings (See FIG. 2G).

Then, Au plating and Pd plating are respectively applied to the sites not covered with the second resist mask on the metal sheet, so that an Au plating layer and a Pd plating layer are formed in this order to have predetermined thicknesses respectively (for example, Au plating layer of 0.003 μm and Pd plating layer of 0.03 μm) as the first plating layer 11.

After that, Ni plating (or Cu plating) is applied to the Pd plating layer for about 4 μm, so that, as the plating layer 12 that is to become wiring portions, a Ni plating layer (or a Cu plating layer) is formed as having the same plating boundaries in a plan view as the first plating layer. Also, the Ni plating layer (or Cu plating layer) that is to become wiring portions preferably undergoes roughening treatment. FIG. 2H shows the state at this stage.

The total thickness of the laminated plating layer configured of the first plating layer 11 and the plating layer 12 that is to become wiring portions should be 5 μm or less. A plating thickness exceeding 5 μm is not preferable. When a third resist mask for forming the later-described second plating layer is formed to cover the first plating layer 11 and the plating layer 12 that is to become wiring portions, an excessive protrusion of the laminated plating layer from the metal sheet would allow easy entry of air in beneath the third resist mask.

In the case where a Ni plating layer is formed as the plating layer 12 that is to become wiring portions, roughening treatment on the Ni plating layer is carried out by subjecting the surface of the Ni plating layer to etching. In the case where a Cu plating layer is formed as the plating layer 12 that is to become wiring portions, roughening treatment on the Cu plating layer is carried out by subjecting the surface of the Cu plating layer to anodizing treatment or etching.

The metal of which the plating layer on the semiconductor-element-mounting-surface side (i.e. nearest to the metal sheet) in the first plating layer 11 is made is appropriately selectable among Ni, Pd, Au, Ag, Sn, Cu and the like as one that is needed for flip-chip connection.

Then, the second resist mask on the front-side surface is peeled off (See FIG. 2I). Then, the front surface, which has been peeled, of the metal sheet is laminated with dry film resist R3 (See FIG. 2J). After peeling off the second resist mask and before laminating with the dry film resist R3, the metal sheet surface preferably is subjected to roughening treatment upon use of, as a mask, the plating layer 12 that is to become wiring portions formed on the metal sheet.

Then, the dry film resist R3 on the front-surface side is exposed and developed upon use of a glass mask that carries a pattern (here, referred to as a pattern B) for covering the concavity 1 a and forming a plating layer to be additionally layered on sites that are to become external terminals within areas of the previously-formed plating layer that is to become wiring portions, to turn into a third resist mask having pattern-B openings (See FIG. 2K).

Then, Ni plating, Pd plating and Au plating are sequentially applied to the surface not covered with the third resist mask, on the Ni plating layer (or Cu plating layer) constituting the plating layer 12 that is to become wiring portions, so that a Ni plating layer, a Pd plating layer and an Au plating layer arranged in this order in the second plating layer 13 have predetermined thicknesses respectively while the upper surface of the uppermost plating layer (Au plating layer) is lower than the upper surface of the third resist mask. FIG. 2H shows this state. Preferably, each plating is carried out to form a concavity resulted from the upper surface of the uppermost plating layer being lower than the upper surface of the third resist mask by 3 to 13 μm. By doing so, when solder bonding with external equipment is to be made after a semiconductor device is mounted, the solder easily pools in the concavity and thus solder bleeding is avoided. The Ni plating layer is formed to have a thickness of 20 to 50 μm. Alternatively, Pd plating and Au plating may be applied, to provide a Pd plating layer and an Au plating layer in this order with respective predetermined thicknesses without providing the Ni plating layer. The metal of which the plating layer that is to become an external-terminal bonding surface in the second plating layer 13 is made is appropriately selectable among Ni, Pd, Au, Sn, and the like as one that can be solder-bonded to an external base material.

Then, the resist masks on the both surfaces are peeled off (See FIG. 2M).

Then, on the side of the metal sheet where the respective plating layers corresponding to internal terminals, wiring portions and external terminals are formed, while the upper faces of the second plating layer 13, which is to become external terminals, are left uncovered, the remaining sites are resin-sealed (See FIG. 2N). When resin-sealing is carried out, uneven height of terminals owing to the plating for terminal-patterning may cause the resin to flow onto the external terminal surface. In this case, the surface of the sealing resin is to be polished to expose the external terminal surface.

Then, etching is performed to remove the metal sheet by dissolution or peeling so that, as shown in FIG. 2O, the surface of the first plating layer 11, which is to become internal terminals, is uncovered at the same level as the bottom surface 15 a of the resin layer 15 as well as a resin frame portion 16′ is integrally formed with the resin layer 15 around the margin of the aggregate of wiring members for semiconductor devices. Thereby, the multi-row wiring member for semiconductor device of this embodiment mode is completed.

Manufacturing of a semiconductor device using the wiring member for semiconductor device of the first embodiment mode thus manufactured is conducted as shown below. FIGS. 3A-3F are explanatory diagrams that show one example of the manufacturing process for a resin-sealed semiconductor device using the multi-row wiring member for semiconductor device of the first embodiment mode manufactured via the manufacturing process shown in FIGS. 2A-20. FIGS. 4A-4B are diagrams that show the state where flip-chip mounting of a semiconductor element on the individual wiring member for semiconductor device is achieved in the manufacturing process shown in FIGS. 3A-3F, where FIG. 4A is a plan view as viewed from the semiconductor-element-mounting side, and FIG. 4B is a sectional view of FIG. 4A.

First, a semiconductor element 20 is mounted on the internal-terminal surface side of the wiring member for semiconductor device shown in FIG. 3A, and electrodes of the semiconductor element 20 are connected with the internal terminals, which are uncovered at the same level as the bottom surface 15 a of the resin layer 15, via a solder ball 14 (See FIG. 3B, FIG. 4A and FIG. 4B). In the wiring member for semiconductor device of the first embodiment mode, since the surfaces of the internal terminals as uncovered are at the same level as the bottom surface 15 a of the resin layer 15, the semiconductor element 20 can be stably mounted.

Then, a gap around the internal-terminal side of the semiconductor element 20 connected via the solder ball 14 is sealed with a predetermined sealing material 17 (See FIG. 3C).

Then, the surface on which the semiconductor element 20 is mounted is sealed with a sealing resin 18 (See FIG. 3D).

Then, cutting is made for individual semiconductor device regions (See FIG. 3E).

Thereby, the semiconductor device is completed. FIGS. 3A-3E are shown without changing the vertical direction of the wiring member for semiconductor device.

The semiconductor device as completed is mounted on an external member. In this case, since only the external terminals are left uncovered in reference to the resin, they can be easily connected with connecting terminals provided on the external member.

According to the multi-row wiring member for semiconductor device of the first embodiment mode, since the resin frame portion 16′ is integrally formed with the resin layer 15 at the margin around an aggregate of wiring members for semiconductor devices, the resin frame portion reinforces the multi-row wiring member for semiconductor device, to assure a strength that makes the multi-row wiring member for semiconductor device hardly deformable even if conveyed.

Also, according to the multi-row wiring member for semiconductor device of the first embodiment mode, since the individual wiring member for semiconductor device forms laminated pieces of plating layers 11, 12 and 13 in which the internal terminals and the external terminals are connected via the wiring portions, the respective mounting pitches of the internal terminals and the external terminals are adjustable in accordance with design.

Also, according to the multi-row wiring member for semiconductor device of the first embodiment mode, since each laminated piece of plating layers 11, 12 and 13 in which an internal terminal and an external terminal are connected via a wiring portion is formed to have substantially an L shape or an inverted T shape in a side view, adhesion to the resin layer 15 is improved and thus prevents the metal film forming the terminals from coming off the resin layer.

Also, according to the multi-row wiring member for semiconductor device of the first embodiment mode, since the configuration is made so that the second plating layer 13, which is to become external terminals, is formed on partial areas within areas of the plating layer 12 that is to become wiring portions, the second plating layer 13 can be made small and thus, as the external terminals left uncovered on the back side (upper side in FIG. 3F) of the semiconductor device, is prevented from dropping or coming off.

Also, according to the multi-row wiring member for semiconductor device of the first embodiment mode, in the case where the internal terminal and the external terminal are shaped into a rectangular having the same width in each laminated piece of the plating layers as shown in FIGS. 1D and 1E, a large area can be secured for the internal terminal and thus the product is widely applicable to a variety of semiconductor elements different in pitch of electrodes.

Also, according to the multi-row wiring member for semiconductor device of the first embodiment mode, the external terminals having a thickness different from the internal terminals and the wiring portions are pre-provided, and the internal terminals and the wiring portions are sealed with the resin layer while only the external terminals are uncovered on the side of the top surface of the resin layer. This configuration makes it unnecessary to remove the metal sheet by etching or to provide an insulating layer having openings at connection faces with external members in the manufacturing process for a semiconductor device, to result in a reduced number of steps in the manufacturing process for a semiconductor device and improved productivity.

Also, according to the first embodiment mode, the multi-row wiring member for semiconductor device is configured to include only the laminated plating film and the resin layer, and thus, in resin-sealing after flip-chip mounting, only the resin layer 15 and the uncovered plating film are sealed with a sealing resin 18, while the surface of the base material (metal sheet), which greatly differs in expansion coefficient from the resin, is not contacted with the sealing resin. Therefore, warpage after curing of the sealing resin is moderated. To be specific, in the case of resin-sealing of the resin layer, since the resin layer and the sealing resin are materials having similar physical characteristics, a difference between the two materials in thermal shrinkage or thermal expansion after curing of the sealing resin is smaller in comparison with the case of resin-sealing of the metal sheet forming a base material. In addition, no base material is removed after formation of the sealing resin portion. As a result, warpage after curing of the sealing resin is moderated.

Furthermore, according to the multi-row wiring member for semiconductor device of the first embodiment mode, since removal of the metal sheet as a base material by etching and processes (application of solder resist, exposure, and development) for forming openings at connection faces with external equipment are dispensable in the manufacturing process for a semiconductor device, seeping-in moisture or liquid agent could not deteriorate the semiconductor device.

Therefore, according to the first embodiment mode, there can be provided a multi-row wiring member for semiconductor device that enables mass production of a highly-reliable resin-sealed semiconductor device with high yield through a reduced number of steps and a manufacturing method for the same multi-row wiring member for semiconductor device; the wiring member enables reduction in thickness and size of the semiconductor device, improves adhesion between a plating film that forms terminal portions and a resin, achieves uniform height of the internal terminal surface on which the semiconductor element is to be mounted and internal terminal portions to be electrically connected with the semiconductor element, eliminates, in the manufacturing process for the semiconductor device, the step of removing the metal sheet by etching and the step of forming openings that uncover external terminal portions alone, and moderating a warpage of the sealing resin as cured.

Embodied Example

Next, description will be made of an embodied example of the multi-row wiring member for semiconductor device and the manufacturing method therefor.

Although pre-treatment and post-treatment including chemical cleaning, aqueous washing and the like were carried out in each step, they are common treatment and thus description is omitted.

First, a copper material having a thickness of 0.15 mm, which is for the use as a lead frame material also, was prepared as a metal sheet (See FIG. 2A).

In the step of forming a first resist mask, dry film resist R having a thickness of 25 μm was made to laminate both surfaces of the metal sheet (see FIG. 2B).

Then, the dry film resist R on the front surface side was exposed and developed upon use of a glass mask carrying a pattern for forming an opening at a site that is to be a margin around an aggregate of wiring members for semiconductor devices, to form a first resist mask having an opening at a site that is to be a margin around an aggregate of wiring members for semiconductor devices. Regarding the dry film resist R on the back surface side, exposure and development were carried out upon use of a glass mask that allows the entire surface to be exposed, to form a first resist mask covering the entire surface. The exposure and development were carried out in the same manner as conventional one; the exposure of the dry film resist for transferring the respective patterns was carried out by, upon closely fitting a glass mask for exposure to the dry film resist, irradiating them with ultraviolet rays, and the development was carried out with sodium carbonate (See FIG. 2C).

Then, half-etching was performed from the front-surface side of the metal sheet, to form a concavity 1 a in a metal surface left uncovered at the opening (See FIG. 2D).

Then, the first resist mask on the front-surface side was peeled off (See FIG. 2E), and the front surface, which has been peeled, was laminated with dry film resist R2 (See FIG. 2F).

Then, the dry film resist R2 on the front-surface side was exposed and developed upon use of a glass mask that carried a pattern A for covering the concavity 1 a and forming a plating coat at predetermined sites, to form a second resist mask having openings at sites to be plated (See FIG. 2G).

In the next plating step, after a common pre-treatment for plating, the metal sheet free from covering by the second resist mask on the front side was plated so that Au of 0.01 μm, Pd of 0.03 μm, and Ni of 4.0 μm were formed in this order (See FIG. 2H).

Then, the second resist mask on the front-side surface was peeled off (See FIG. 2I), and dry film resist R3 was made to laminate the front surface (see FIG. 2J). At that time, it was necessary to select the thickness of the resist according to the thickness of the second plating layer to be formed. In this embodied example, since the second plating layer was to be formed to have a thickness of 15 to 40 μm, a resist having a thickness of 50 μm was used only for the front surface side so that the uppermost surface of the plating layers is below the upper surface of the second resist mask, and a resist having a thickness of 25 μm was used for the back surface side.

Then, a third resist mask was formed by exposure and development upon use of a glass mask that carried a pattern B for forming a plating that is to be additionally layered on sites that were within the previously-formed plating layer and that were to become external terminals (See FIG. 2K).

In the next plating step, an Ni plating surface free from covering by the third resist mask as formed was plated so that Ni of 20.0 μm, Pd of 0.03 μm, and Au of 0.01 μm were formed in this order (see FIG. 2L), and then the resist masks on the both sides were removed (see FIG. 2M).

Then, on the side of the metal sheet where the respective plating layers corresponding to internal terminals, wiring portions and external terminals have been formed, while the upper faces of the second plating layer 13, which were to become external terminals, were left uncovered, the concavity 1 a and the remaining sites were sealed with a resin 15 (See FIG. 2N).

Then, the metal sheet was removed by etching, to complete a multi-row wiring member for semiconductor device provided with a resin frame portion 16′ formed around the margin of an aggregate of wiring members for semiconductor devices (See FIG. 2O).

Then, a semiconductor element was mounted on the side that had once adjoined the metal sheet, to establish electrical conduction with the internal terminals with the plating layer fixed by the resin layer 15 of the multi-row wiring member for semiconductor device as completed being used as a wiring (see FIG. 3B), the semiconductor-element-mount portion was resin-sealed (See FIG. 3D), and cutting was made for individual semiconductor device regions. Thereby obtained was a semiconductor device in which faces of the external terminals were free from covering by the surface 15 b of the resin layer 15 (see FIG. 3E).

Although the embodiment mode and the embodied example of the multi-row wiring member for semiconductor device are described above, the multi-row wiring member for semiconductor device is not limited to the configuration of the above-described embodiment mode and the embodied example.

For example, in the multi-row wiring member for semiconductor device of the first embodiment mode, used for the first plating layer are Au and Pd, used for the plating layer that is to become wiring portions is Ni, used for the second plating layer is Ni, Pd and Au. However, the combination of the plating used for forming the first plating layer, the plating layer that is to become wiring portions, and the second plating layer is not limited thereto. As modified examples, the multi-row wiring member for semiconductor device according to the present invention may be configured by combining the first plating layer, the plating layer that is to become wiring portions, and the second plating layer formed by plating as shown in the following Table 1. In Table 1, plating is shown as being applied in order from the top of the column in each modified example.

TABLE 1 Combination of Plating Constituting Wiring Member for Semiconductor Device Modified Example 1 2 3 4 5 6 7 8 9 1st Plating Layer Au Ag Au Au Ag Au Ag Pd Pd Pd Pd Pd Plating Layer That Ni Ni Ni Ni Ni Ni Ni Ni Ni Is To Become Wiring Portions 2nd Plating Layer Au Au Au Pd Pd Pd Au Au Pd Au Au Au Au 

1. A multi-row wiring member for semiconductor device configured of a plurality of wiring members for semiconductor devices arrayed in a matrix including: a resin layer; a first plating layer, which is to become internal terminals, formed in the resin layer with lower faces thereof being uncovered at predetermined sites in a bottom surface of the resin layer; a plating layer that is to become wiring portions, connected with the first plating layer in the resin layer; and a second plating layer, which is to become external terminals, formed, in the resin layer on partial areas within areas of the plating layer that is to become wiring portions, with upper faces thereof being uncovered on a top-surface side of the resin layer, wherein a side view of each laminated piece of plating layers forming one of the internal terminals, one of the wiring portions, and one of the external terminals substantially has an L shape or an inverted T shape, and wherein, on a bottom-surface side of the resin layer, a resin frame portion is integrally formed with the resin layer at a site that is to be a margin around an aggregate of individual wiring members for semiconductor devices arrayed in a matrix.
 2. The multi-row wiring member for semiconductor device according to claim 1, wherein the plating layer that is to become wiring portions is formed on the first plating layer with plating boundaries thereof coinciding with plating boundaries of the first plating layer.
 3. The multi-row wiring member for semiconductor device according to claim 1, wherein an upper surface of the plating layer that is to become wiring portions formed on the first plating layer is a roughened surface.
 4. The multi-row wiring member for semiconductor device according to claim 1, wherein a bottom surface of the resin layer in which the first plating layer is left uncovered is a rough surface.
 5. A method for manufacturing a multi-row wiring member for semiconductor device configured of a plurality of wiring members for semiconductor devices arrayed in a matrix including: a step of forming, on a front surface of a metal sheet, a first resist mask having an opening at a site that is to be a margin around an aggregate of wiring members for semiconductor devices arrayed in a matrix; a step of performing half-etching from a front-surface side of the metal sheet, to form a concavity in a metal surface left uncovered at the opening; a step of peeling off the first resist mask formed on the front surface of the metal sheet; a step of forming, on the front surface of the metal sheet, a second resist mask covering the concavity and having pattern-A openings; a step of forming, in the pattern-A openings, a first plating layer, which is to become internal terminals, and a plating layer that is to become wiring portions, connected with the first plating layer; a step of peeling off the second resist mask formed on the front surface of the metal sheet; a step of forming, on a front-surface side of the metal sheet, a third resist mask covering the concavity and having pattern-B openings that leave uncovered partial areas within areas of the plating layer that is to become wiring portions; a step of forming a second plating layer, which is to become external terminals, in the pattern-B openings; a step of peeling off the third resist mask formed on the front side of the metal sheet; a step of forming a resin layer on the metal sheet and the plating layer that is to become wiring portions at sites free from the second plating layer while leaving upper faces of the second plating layer uncovered and filling the concavity; and a step of removing the metal sheet by etching or peeling.
 6. The method for manufacturing a multi-row wiring member for semiconductor device according to claim 5, wherein the plating layer that is to become wiring portions is formed on the first plating layer to have plating boundaries coinciding with plating boundaries of the first plating layer.
 7. The method for manufacturing a multi-row wiring member for semiconductor device according to claim 5, wherein an upper surface of the plating layer that is to become wiring portions undergoes roughening treatment after formation of the plating layer that is to become wiring portions and before formation of the third resist mask or the plating layer that is to become wiring portions is formed as a roughened plating layer.
 8. The method for manufacturing a multi-row wiring member for semiconductor device according to claim 5, further comprising a step of carrying out roughening treatment of the surface of the metal sheet upon using, as a mask, the plating layer that is to become wiring portions formed on the metal sheet after removal of the first resist mask and the second resist mask formed on the respective surfaces of the metal sheet. 